Journal of Neurophysiology

Sikes, R. W.; Vogt, B. A.

doi: N/Apmid: 1479441

Abstract 1. Single-unit responses in area 24 of cingulate cortex were examined in halothane-anesthetized rabbits during stimulation of the skin with transcutaneous electrical (TCES, 3-10 mA), mechanical (smooth or serrated forceps to the dorsal body surface or graded pressures of 100-1,500 g to the stabilized ear) and thermal (> 25 degrees C) stimulation. 2. Of 542 units tested in cingulate cortex, 150 responded to noxious TCES (> or = 6 mA), 93 of 221 units tested responded to noxious mechanical (serrated forceps) and 9 of 47 units tested responded to noxious heat (> 43 degrees C) stimuli. Twenty-five percent of the units that responded to noxious mechanical stimuli also responded to noxious heat stimuli. The only innocuous stimulus that evoked activity in cingulate cortex was a "tap" to the skin and this was effective for 11 of 14 tested units. 3. In 74 units that produced excitatory responses to TCES of the contralateral ear, response latency was 166 +/- 11.3 (SE) ms and response duration was 519 +/- 52.1 ms. 4. Twenty of the 150 units that responded to noxious TCES were initially inhibited. These responses were usually < 1 s in duration (17 of 20 units), whereas responses in the other 3 lasted for over 20 s. 5. Most units had broad receptive fields, because noxious mechanical stimuli anywhere on the dorsal surface of the rabbits, including the face and ears, evoked responses. A small number of units for which the entire body surface was tested (3 of 15 units) had receptive fields limited to the ears, rostral back, and forepaws. 6. Fifteen of 33 units tested had no preferential responses to noxious TCES of the ipsilateral and contralateral ears. Of the remaining units, 10 had a greater response to contralateral and 8 had a greater response to ipsilateral stimuli. 7. The locations of 186 units were histologically verified. Most nociceptive cingulate units were in dorsal area 24b in layers III (n = 35), II (n = 13), or V (n = 9). 8. Cortical knifecut lesions were made in five rabbits to determine if the responses in area 24 were dependent on lateral or posterior cortical inputs. These lesions did not alter the percentage of units driven by noxious stimuli nor response latency. 9. Injections of lidocaine were made into medial parts of the thalamus in six animals and injection and recording sites analyzed histologically.(ABSTRACT TRUNCATED AT 400 WORDS) Copyright © 1992 the American Physiological Society

Huebner, W. P.; Leigh, R. J.; Seidman, S. H.; Thomas, C. W.; Billian, C.; DiScenna, A. O.; Dell'Osso, L. F.

doi: N/Apmid: 1479444

Abstract 1. We used a modeling approach to test the hypothesis that, in humans, the smooth pursuit (SP) system provides the primary signal for cancelling the vestibuloocular reflex (VOR) during combined eye-head tracking (CEHT) of a target moving smoothly in the horizontal plane. Separate models for SP and the VOR were developed. The optimal values of parameters of the two models were calculated using measured responses of four subjects to trials of SP and the visually enhanced VOR. After optimal parameter values were specified, each model generated waveforms that accurately reflected the subjects' responses to SP and vestibular stimuli. The models were then combined into a CEHT model wherein the final eye movement command signal was generated as the linear summation of the signals from the SP and VOR pathways. 2. The SP-VOR superposition hypothesis was tested using two types of CEHT stimuli, both of which involved passive rotation of subjects in a vestibular chair. The first stimulus consisted of a "chair brake" or sudden stop of the subject's head during CEHT; the visual target continued to move. The second stimulus consisted of a sudden change from the visually enhanced VOR to CEHT ("delayed target onset" paradigm); as the vestibular chair rotated past the angular position of the stationary visual stimulus, the latter started to move in synchrony with the chair. Data collected during experiments that employed these stimuli were compared quantitatively with predictions made by the CEHT model. 3. During CEHT, when the chair was suddenly and unexpectedly stopped, the eye promptly began to move in the orbit to track the moving target. Initially, gaze velocity did not completely match target velocity, however; this finally occurred approximately 100 ms after the brake onset. The model did predict the prompt onset of eye-in-orbit motion after the brake, but it did not predict that gaze velocity would initially be only approximately 70% of target velocity. One possible explanation for this discrepancy is that VOR gain can be dynamically modulated and, during sustained CEHT, it may assume a lower value. Consequently, during CEHT, a smaller-amplitude SP signal would be needed to cancel the lower-gain VOR. This reduction of the SP signal could account for the attenuated tracking response observed immediately after the brake. We found evidence for the dynamic modulation of VOR gain by noting differences in responses to the onset and offset of head rotation in trials of the visually enhanced VOR.(ABSTRACT TRUNCATED AT 400 WORDS) Copyright © 1992 the American Physiological Society

Vaughan, C. W.; Satchell, P. M.

doi: N/Apmid: 1362215

Abstract 1. The effect of the sympathetic innervation on the bladder detrusor muscle was assessed in pentobarbitone-anesthetized cats by measuring the changes in bladder wall tension that occurred during sympathetic ganglion blockade after filling the bladder at a natural rate. 2. At a point 60% of the way through the continence process, systemic sympathetic blockade was produced by intravenous trimethaphan, and selective blockade of postganglionic hypogastric nerve activity was produced by application of trimethaphan to the exposed inferior mesenteric ganglia. The level of blockade was monitored with an in-continuity hypogastric nerve recording. 3. During both systemic and selective ganglion blockade, there was an increase in baseline transmural bladder pressure and a decrease in the amplitude of nonmicturating contractions. 4. Although there was no change in the mean level of transmural bladder pressure during either systemic or selective blockade, there was a significant increase in the mean level of bladder wall mechanoreceptor discharge, suggesting that before the blockade sympathoinhibitory effects were greater than sympathoexcitatory effects. 5. Measurement of bladder wall mechanoreceptor discharge before and during ganglion blockade revealed a net sympathoinhibitory influence on the level of bladder wall tension under natural filling conditions. These results confirm that the detrusor muscle of the feline bladder is under both sympathoinhibitory and sympathoexcitatory influences for a significant portion of the continence process. Copyright © 1992 the American Physiological Society

Angelaki, D. E.; Perachio, A. A.; Mustari, M. J.; Strunk, C. L.

doi: N/Apmid: 1479452

Abstract 1. During constant velocity off-vertical axis rotations (OVAR) in the dark a compensatory ocular nystagmus is present throughout rotation despite the lack of a maintained signal from the semicircular canals. Lesion experiments and canal plugging have attributed the steady-state ocular nystagmus during OVAR to inputs from the otolith organs and have demonstrated that it depends on an intact velocity storage mechanism. 2. To test whether irregularly discharging otolith afferents play a crucial role in the generation of the steady-state eye nystagmus during OVAR, we have used anodal (inhibitory) currents bilaterally to selectively and reversibly block irregular vestibular afferent discharge. During delivery of DC anodal currents (100 microA) bilaterally to both ears, the slow phase eye velocity of the steady-state nystagmus during OVAR was reduced or completely abolished. The disruption of the steady-state nystagmus was transient and lasted only during the period of galvanic stimulation. 3. To distinguish a possible effect of ablation of the background discharge rates of irregular vestibular afferents on the velocity storage mechanism from specific contributions of the dynamic responses from irregular otolith afferents to the circuit responsible for the generation of the steady-state nystagmus, bilateral DC anodal galvanic stimulation was applied during optokinetic nystagmus (OKN) and optokinetic afternystagmus (OKAN). No change in OKN and OKAN was observed.(ABSTRACT TRUNCATED AT 250 WORDS) Copyright © 1992 the American Physiological Society

Lou, J. S.; Bloedel, J. R.

doi: N/Apmid: 1479447

Abstract 1. The purpose of these experiments is to test the hypothesis that the synchronous activation of sagittally aligned Purkinje cells by a physiologically relevant stimulus is associated with an increase in the simple spike responses of the same neurons. 2. This hypothesis was tested using a perturbed locomotion paradigm in decerebrate locomoting ferrets. The responses of 3-5 sagittally aligned Purkinje cells were recorded simultaneously in response to the intermittent perturbation of the forelimb during swing phase. A data analysis is introduced, the real time postsynaptic response (RTPR), that permits the quantification of the simple spike responses of Purkinje cells in a manner that can be related to their complex spike responses on a trial-by-trial basis. 3. The data support the above hypothesis by illustrating that the amplitude of the combined simple spike responses across the population of Purkinje cells is correlated with the extent to which their climbing fiber inputs are synchronously activated. These findings together with an analysis of the gain-change ratio support the view that the synchronous climbing fiber input may be responsible for mediating this increased responsiveness. 4. More generally, the data suggest that the task- and/or behaviorally dependent activation of sagittal strips of climbing fiber inputs may provide a mechanism whereby the responsiveness of discrete populations of Purkinje cells can be selectively regulated, specifying the groups of neurons that will be most dramatically modulated by mossy fiber inputs activated by the same conditions. Copyright © 1992 the American Physiological Society

Rizzo, M. A.; Nonner, W.

doi: N/Apmid: 1479440

Abstract 1. Somatic K currents of cultured hippocampal, striatal, and spinal cord neurons of embryonic rat were recorded under voltage clamp in membrane spheres ("blebs") excised by means of a tight-seal pipette. 2. The somatic K current in blebs was subject to rapid and near complete inactivation during 300-ms depolarizations, whereas whole-cell K currents included a substantial maintained component. Size and kinetic properties of bleb and whole-cell currents were stable throughout the recording period. 3. The steady-state inactivation of somatic A current was steeply voltage dependent and complete near voltage levels that activated current, whereas peak conductances did not saturate during depolarizations up to +90 mV. Activation started with a delay. Half-times of activation decreased with depolarization, but half-times of inactivation varied little with depolarization. Recovery from inactivation followed a sigmoidal time course with half-times of approximately 50 ms. 4. Half-times of activation and inactivation varied over more than an order of magnitude between individual neurons. Midpoint potentials of inactivation and peak conductance varied over approximately 40 mV. The parameter ranges of hippocampal, striatal, and spinal cord neurons overlapped. 5. Individual soma membranes revealed signs of K channel heterogeneity in their 4-aminopyridine block, current fluctuations, and current kinetics. On the other hand, currents elicited after conditioning pulses that established varied degrees of steady-state inactivation or of recovery from full inactivation had superimposable time courses. 6. The described characteristics of the somatic A channels are compared with those reported for the RCK4, Raw3, and mShal products expressed in Xenopus oocytes. Whereas the ranges of voltage dependencies and of most kinetic characteristics are compatible among native and cloned channels, these three cloned channels recover much more slowly from inactivation. In addition, inactivation in native channels, unlike that in RCK4 and Raw3 channels, was stable after excision in a subcellular fragment. Copyright © 1992 the American Physiological Society

Broussard, D. M.; Lisberger, S. G.

doi: N/Apmid: 1479453

Abstract 1. Previous studies have described a subpopulation of interneurons in the vestibuloocular reflex (VOR) pathways that express large changes in their responses to head turns in conjunction with motor learning in the VOR. These neurons are called flocculus target neurons (FTNs) because they are inhibited at monosynaptic latencies by stimulation of the flocculus and ventral paraflocculus. 2. Electrical stimulation of the vestibular labyrinth revealed that FTNs receive excitatory monosynaptic inputs from the ipsilateral vestibular labyrinth and longer-latency, excitatory inputs from the contralateral labyrinth. 3. Our data show that commissural inhibition, which has been thought to be an important feature of vestibular processing, does not provide the dominant inputs from the contralateral labyrinth to FTNs. Instead, the inputs from both labyrinths are excitatory and may be functionally antagonistic. Changes in the balance of excitatory inputs from the two horizontal canals to FTNs could contribute to motor learning in the VOR. Copyright © 1992 the American Physiological Society

Rind, F. C.; Simmons, P. J.

doi: N/Apmid: 1479436

Abstract 1. The "descending contralateral movement detector" (DCMD) neuron in the locust has been challenged with a variety of moving stimuli, including scenes from a film (Star Wars), moving disks, and images generated by computer. The neuron responds well to any rapid movement. For a dark object moving along a straight path at a uniform velocity, the DCMD gives the strongest response when the object travels directly toward the eye, and the weakest when the object travels away from the eye. Instead of expressing selectivity for movements of small rather than large objects, the DCMD responds preferentially to approaching objects. 2. The neuron shows a clear selectivity for approach over recession for a variety of sizes and velocities of movement both of real objects and in simulated movements. When a disk that subtends > or = 5 degrees at the eye approaches the eye, there are two peaks in spike rate: one immediately after the start of movement; and a second that builds up during the approach. When a disk recedes from the eye, there is a single peak in response as the movement starts. There is a good correlation between spike rate and angular acceleration of the edges of the image over the eye. 3. When an object approaches from a distance sufficient for it to subtend less than one interommatidial angle at the start of its approach, there is a single peak in response. The DCMD tracks the approach, and, if the object moves at 1 m/s or faster, the spike rate increases throughout the duration of object movement. The size of the response depends on the speed of approach. 4. It is unlikely that the DCMD encodes the time to collision accurately, because the response depends on the size as well as the velocity of an approaching object. 5. Wide-field movements suppress the response to an approaching object. The suppression varies with the temporal frequency of the background pattern. 6. Over a wide range of contrasts of object against background, the DCMD gives a stronger response to approaching than to receding objects. For low contrasts, the selectivity is greater for objects that are darker than the background than for objects that are lighter. Copyright © 1992 the American Physiological Society

Picard, N.; Smith, A. M.

doi: N/Apmid: 1479451

Abstract 1. Two monkeys were trained to grasp, lift, and hold an object within a vertical position window. A downward force-pulse perturbation was delivered during stationary object holding to simulate slip of the object due to gravity. The responses evoked by the perturbation were studied in 189 neurons of the hand area of the primary motor cortex. In addition, the slip-evoked responses were compared with the modulation of neural discharge with textures and weights described in the previous paper. 2. The perturbation evoked responses with sharp onsets in the majority of motor cortical neurons (115/189, 61%) active during the task. The majority of the responses were of sufficiently short latency (43.17 +/- 17.24 ms, mean +/- SD) to have participated in the reflex grip force increase that followed at latencies from 50 to 100 ms. 3. Although a similar proportion of neurons with cutaneous (43/70) or proprioceptive (35/59) receptive fields (RFs) were responsive to the perturbation, the cutaneous afferents provided a stronger excitation of motor cortical cells than the feedback originating from proprioceptive receptors. 4. The covariation of the neural discharge related to the surface texture of the grasped object and the responsiveness to object slip was studied in 89 cells tested with the perturbation and with more than one surface texture on unperturbed trials. Within this population, motor cortical cells with cutaneous RFs were more sensitive to the perturbation (25/31) than neurons receiving proprioceptive input (8/16). Furthermore, all (17/17) neurons with cutaneous RFs that were more active with the smooth than with the rough surface textures showed a vigorous response to the perturbation. 5. A detectable downward displacement of the object was not always necessary to excite neurons with cutaneous RFs and whose activity increased with the smooth textures. Their sensitivity to the perturbation was consistent with the hypothesis that the cutaneous afferent activity generated by object slips or shear forces on the skin contributed to the increased discharge when lifting objects of slippery surface textures. The activity of these slip- or shear-sensitive cells may have contributed to the reflex grip force increases and to the greater sustained muscular activity needed to lift smooth objects. 6. Ten cells that were excited by stroking of the glabrous skin of the hand decreased their discharge frequency during the task even though their RFs were in direct contact with the object. Most of these neurons (7/10) did not respond to the object slip, and three cells had very weak responses to the perturbation.(ABSTRACT TRUNCATED AT 400 WORDS) Copyright © 1992 the American Physiological Society

Kent, P. F.; Mozell, M. M.

doi: N/Apmid: 1479446

Abstract 1. Fluorescence changes in the dye (WW 781) were monitored at 100 contiguous sites in a 10 x 10-pixel array on the bullfrog and salamander olfactory mucosas every 10 ms in response to odorous stimuli. The odorants were d-limonene, butanol, and amyl acetate, each presented at two concentrations with a 3:1 ratio. 2. The fluorescence signals elicited by these odorous stimuli were nearly identical in shape and time course to the electro-olfactograms (EOGs) recorded from the same animal under identical conditions. Like the EOGs, the fluorescence signals exhibited adaptation and were abolished by both Triton X-100 and ether. There was no measurable fluorescence when the tissue was not stained with the dye, and there was no change in fluorescence when, for stained tissue, nonodorized, humidified air was presented as the stimulus. 3. This technique presumably monitors the same events as the EOG, but has the advantage of simultaneously recording the odorant-induced activity from multiple sites across most of the mucosa. Thus this technique preserves subtle differences heretofore lost by other techniques both in the coarseness of their matrices and in the variability generated by trying to piece together, into one collage, results from numerous presentations given at different times. 4. In all preparations, there was a larger difference in the inherent activity patterns (derived from response magnitudes) between different odorants than between different concentrations of the same odorant. These differences were largest on the mucosa lining the floor of salamander's olfactory sac. d-limonene and butanol gave their largest responses near the internal and external nares, respectively, whereas the responses for amyl acetate were more uniform across the mucosal sheet. In contrast to the salamander, smaller differences were observed for both the roof and the floor of the bullfrog's olfactory sac. For the floor, both amyl acetate and d-limonene elicited similar patterns of response magnitude, whereas butanol differed from each of these odorants by eliciting a larger response on the anteriolateral aspect of the mucosa and a lesser response on the remainder. For the roof, different odorants produced different activity patterns, which had profiles not simply described as regions of maximal and minimal responsiveness. 5. Different inherent activity patterns based on temporal characteristics of the fluorescence responses were also observed for different odorants. Each odorant produced a different pixel-by-pixel pattern for the times at which the responses started and ended. For any given odorant, these temporal patterns paralleled the patterns given by response magnitudes.(ABSTRACT TRUNCATED AT 400 WORDS) Copyright © 1992 the American Physiological Society